Projection Module for an Automobile Headlight
The invention relates to a projection module (100) for an automobile headlamp. The module (100) includes at least one semiconductor emission source (101) to emit electromagnetic radiation, a reflector (103) to reflect the emitted irradiation, a baffle arrangement (104) to shade at least a portion of the reflected irradiation, and a projection lens (105) to project the reflected irradiation and the irradiation passing by the baffle arrangement (104) to create a desired emission distribution from the projection module (100) in front of the automobile. In order to be able to design the projection module (100) to be particularly compact and small-dimensioned, it is proposed that the minimum of one emission source (101) be mounted on, or near, the rear side of the baffle arrangement (104), and the main irradiation direction (111) of the minimum of one emission source (101) be directed into the semi-open space opposite the irradiation-output direction (109) from the projection module (100).
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The invention relates to a projection module for an automobile headlamp. The module includes at least one semiconductor emission source to emit electromagnetic radiation, a reflector to reflect the emitted irradiation, a baffle arrangement to shade at least a portion of the reflected irradiation, and a projection lens to project the reflected irradiation and the irradiation passing by the baffle arrangement to create a desired emission distribution from the projection module in front of the automobile.
Projection modules with one or more LED's (Light Emitting Diodes) as the emission source are known to the State of the Art in various application forms. Depending on the wavelength of the irradiation emitted by the LED's, the projection module may be used to emit visible light, invisible ultraviolet, (UV) or infrared (IR) irradiation. The invisible irradiation serves, for example, to illuminate the roadway in front of an automobile within the scope of a night-vision device (e.g., “Night vision” for Mercedes-Benz or BMW automobiles). The area illuminated using invisible irradiation may be recorded using a UV- or IR-sensitive camera and presented to the driver, e.g., on a screen in the dashboard or by means of projection onto the inner surface of the windshield.
In LED projection modules known to the State of the Art, the LED's and the baffle arrangement are positioned to be spatially separated. This distance between the LED's and the baffle arrangement, and the distance from the baffle arrangement to the projection lens, strongly dictate the minimum design length of the projection system.
Because of the increasing complexity of automobile headlamps, additional illumination functions (e.g., city lights, countryside lights, high-speed highway lights, poor-weather lights, etc.), however, future projection modules that must be integrated into the headlamp and accommodate new design aspects must be as compact and small-dimensioned as possible. There is also the option in LED light modules for automobile headlamp of integrating several LED's or LED arrays or differing system types (projection and reflection) into an illumination module. This, however, requires that a compact and small-dimensioned illumination module be used.
Starting from the State of the Art described, it is the task of the invention to design and expand a projection module for an automobile headlamp of the type mentioned at the outset that is as compact and small-dimensioned as possible.
As a solution to this task, it is proposed, starting with an automobile headlamp of the type mentioned at the outset, that the emission source be mounted on or near the rear side of the baffle arrangement, and that the main irradiation direction of the emission source be directed into the semi-open space against the emission output from the projection module.
By positioning the minimum of one LED on or onto the rear side, of the baffle arrangement, the distance between the LED's and the baffle arrangement is reduced to a minimum. This allows the installation length of the projection module to be significantly reduced so that the installation depth of an automobile headlamp including the projection module based on the invention may be reduced, or the installation space made available within the headlamp housing may be used otherwise, for example for electronic control or regulation circuits, or for additional illumination modules.
The LED projection module includes a baffle arrangement to shade a portion of the irradiation reflected from the reflector. Thus, the module is suited to the creation of a light-distribution scheme with a light-dark limiting line, for example a dimmed-headlamp distribution, fog-lamp distribution, or even an adaptive light-distribution scheme including, for example, city lights, countryside lights, high-speed highway lights, poor-weather lights, etc. The baffle arrangement may be moveable, and particularly may be designed to be foldable about a horizontal axis extending crosswise to the optical axis so that it may be moved into or out of the irradiation path. Thus, the projection module may be switched between high-beam and a light-distribution scheme with a light-dark limiting line. To create an adaptive light-distribution pattern, the baffle arrangement may include several baffle elements that are moveable with respect to one another, particularly pivotable about a horizontal axis extending parallel to the optical axis. The progression of the light-dark limiting line of the light-distribution pattern is determined by optically-active the upper edges of the upper baffle elements.
Per the invention, the LED's are mounted in a plane that essentially corresponds to the extension plane of the baffle arrangement positioned within the beam path. Also, the LED's are directed rearward, i.e., against the direction of vehicle travel, or against the direction of irradiation output. The extension plane of the baffle arrangement preferably extends obliquely, or about a horizontal axis extending essentially crosswise to the optical axis, so that the main irradiation direction of the LED's positioned in the extension plane is not parallel to the optical axis, but rather slightly upward relative to the optical axis.
The minimum of one emission source is thermally connected to a heat sink. Heat transferred from the emission source to the heat sink may be transferred away from the heat sink by means of air or cooling fluid. The size of the projection module based on the invention may also be further reduced in that the heat sink be an integral component of the baffle arrangement. Alternatively or additionally, the heat sink may also be an integral component of a lens bracket that attaches the projection lens to the reflector. It is particularly advantageous if the heat sink is so configured that it replaces a securing frame of the projection module that holds the reflector, the baffle arrangement, and the projection lens in a definite relationship relative to one another. Based on the invention, the light source with bracket and heat sink is mounted in the space between the baffle arrangement or the extension plane of the baffle arrangement and the projection lens.
In the following, an advantageous embodiment of the invention will be described in greater detail using Figures, which show:
The projection module includes at least one light source 2, which in the State of the Art may be in the form of a conventional incandescent bulb, gas filled light or in the form of one or more semiconductor light sources, so-called LED's. The light source 2 emits electromagnetic irradiation whose wavelength lies within the spectra of visible light, or invisible UV or IR light (relevant wavelengths of about 320-380 nm for UV; 380-700 nm for visible light, and about 700 nm-1,600 nm for IR irradiation).
In the known projection modules 1, 10, the minimal installation length is determined by the distance between the light source 2, 12 and the baffle arrangement 4, 14, and by the distance from the baffle arrangement 4, 14 to the projection lens 5, 15. The distance between the light source 2, 12 and the baffle arrangement 4, 14 is relatively large in the known projection modules 1, 10. This is why the installation length of conventional projection modules 1, 10 is relatively large.
Based on the invention, on the other hand, a particularly compact and small-dimensioned LED projection module is proposed that is designated in its entirety by reference index 100.
Based on the cutaway view of the projection module 100 based on the invention in
As
For simplification, the upper reflector half 103a may be observed as an approximate paraboloid, and the lower reflector half 103b may be observed as and ellipsoid. For this, the ellipsoid component of the lower reflector half 103b is configured such that a focal point lies in, or near, the LED's 101, and the other focal point lies in or near the plane 110 of the baffle arrangement 104. This allows the generation of a strong illumination-strength maximum in the resulting light-distribution pattern. The paraboloid component of the upper reflector half 103a is preferably so configured that the focal point of the paraboloid lies in or near the LED's 101. A light-distribution pattern may thus be generated using a basic illumination scheme that is important for illumination of the foreground and for lateral light scattering.
In the embodiment example in
Claims
1. Projection module (100) for an automobile headlamp, with the module (100) including at least one semiconductor emission source (101) to emit electromagnetic radiation, a reflector (103) to reflect the emitted irradiation, a baffle arrangement (104) to shade at least a portion of the reflected irradiation, and a projection lens (105) to project the reflected irradiation and the irradiation passing by the baffle arrangement (104) to create a desired emission distribution from the projection module (100) in front of the automobile, characterized in that the minimum of one emission source (101) be mounted on, or near, the rear side of the baffle arrangement (104), and the main irradiation direction (111) of the minimum of one emission source (101) be directed into the semi-open space opposite the irradiation-output direction (109) from the projection module (100).
2. Projection module (100) as in claim 1, characterized in that the irradiation possesses a wavelength within the visible-light spectrum.
3. Projection module (100) as in claim 1, characterized in that irradiation possesses a wavelength within the invisible infrared-light spectrum.
4. Projection module (100) as in claim 1, characterized in that the reflector is divided into an upper partial reflector (103a) and a lower partial reflector (103b) by an essentially horizontal plane (112).
5. Projection module (100) as in claim 4, characterized in that the upper partial reflector (103a) is displaced forward along the irradiation emission direction from the projection module (100) with respect to the lower partial reflector (103b).
6. Projection module (100) as in claim 1, characterized in that the entire reflector (103) or at least one of the partial reflectors (103a, 103b) is formed as an open-shape reflector.
7. Projection module (100) as in claim 4, characterized in that the upper partial reflector (103a) is shaped as a paraboloid and the lower partial reflector (103b) is shaped as an ellipsoid.
8. Projection module (100) as in claim 7, characterized in that the upper partial reflector (103a) and the lower partial reflector (103b) are positioned such that the focal point of the upper partial reflector (103a) and a first focal point of the lower partial reflector (103b) lies in the area of the minimum of one emission source (101), and a second focal point of the lower partial reflector (103b) lies in the area of the baffle plane (104).
9. Projection module (100) as in claim 4, characterized in that the upper partial reflector (103a) is configured to be pivotable with respect to the lower partial reflector (103b) in order to vary the light-distribution pattern created by the projection module (100).
10. Projection module (100) as in claim 9, characterized in that the lower partial reflector (103b) is in a fixed spatial relationship to the minimum of one emission source (101).
11. Projection module (100) as in claim 9, characterized in that the upper partial reflector (103a) is mounted to be pivotable with respect to a horizontal pivot axis extending crosswise to the optical axis of the projection module (100).
12. Projection module (100) as in claim 9, characterized in that the upper partial reflector (103a) is configured to be displaceable with respect to the lower partial reflector (103b) along an essentially horizontal plane (112).
13. Projection module (100) as in claim 1, characterized in that the minimum of one emission source (101) is thermally connected with a heat sink (107), whereby the heat sink (107) is an integral component of the baffle arrangement (104).
14. Projection module (100) as in claim 1, characterized in that the minimum of one emission source (101) is thermally connected with a heat sink (107), whereby the heat sink (107) is an integral component of a lens bracket (106) that secures the projection lens (105) to the reflector (103).
15. Projection module (100) as in claim 1, characterized in that a reflector (103) or several partial reflectors (103a, 103b) is/are assigned to multiple emission sources (101).
Type: Application
Filed: Aug 28, 2008
Publication Date: Apr 16, 2009
Patent Grant number: 7963684
Applicant: AUTOMOTIVE LIGHTING REUTLINGEN GMBH (Reutlingen)
Inventors: Benjamin Stauss (Reutlingen), Matthias Brendle (Tuebingen)
Application Number: 12/200,047
International Classification: B60Q 1/04 (20060101);